Effect of glycerol on free DNA: A molecular dynamics simulation study

Abstract

Osmolytes are a class of organic solutes that are produced in a variety of organisms in response to stress. They exert diverse effects on macromolecules and their functions. In this work, we investigate the effect of glycerol, one such osmolyte, on the hydration and conformation of four DNA sequences that differ by a single base pair and a random DNA sequence. Molecular dynamics simulations reveal DNA sequence-dependent and glycerol concentration-dependent hydration and DNA conformation. Interestingly, we find that the sequence-dependent changes in the hydration reflects the order of preference of these sequences for star activity of the EcoRI enzyme. However, the changes in DNA conformation do not reflect this order of preference. Interaction energy analyses reveal that the per-glycerol interaction energy with DNA is stronger than the per-water interaction energy with DNA. However, the total interaction energy of glycerol with DNA is lower than that of total water-DNA interaction energy indicating that it might be easier for an approaching DNA-binding protein to displace glycerol than water and thus contributing positively to protein-DNA binding. In a larger context, our study brings attention to the need to investigate the effect of osmolytes on free DNA in order to delineate the role of osmolyte in protein-DNA interactions.